LE TECNOLOGIE INNOVATIVE PER I VELIVOLI DI NUOVA … · Research objective: development of new...

Morphing Structures: 7 years of research at UniNA

3° Incontro - Napoli, 25 Ottobre 2014Scuola Politecnica e delle Scienze di Base

Piazzale V. Tecchio 80, 80125 Napoli

LE TECNOLOGIE INNOVATIVE PER I VELIVOLI DI NUOVA GENERAZIONE

R. Pecora

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7 years of partnership

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Overview of research contracts

2007

ALA-Smart TE: development of new technologies enabling (ATR42) wing trailing edge camber-morphing through SMA-based actuators.

CRIAQ MDO505: development of an adaptive wing box (CS25 A/C) equipped with active skin bumps and morph-ing aileron for drag reduction.

2010

JTI-GRA: High TRL morphing structures enabling wing flap camber variation.

2011

SARISTU: High TRL morphing structures enabling wing trailing edge camber morphing (CS-25 category A/C).

2012

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ALA-Smart Flap (2007-2008)

Cw = 2.574mCf = 0.772md = 1.802m

H

H

morphing law

Flapped airfoil FA

Morphed airfoil (FA )

Investigation domain

Common features of the investigated architectures:• Rib structure as compromise between rigidity and flexibility• SMA beams: acting as actuators and primary structural

elements • Different actuation modalities due to multiple SMA elements

suitably distributed

Research objective: development of new technologies enabling (ATR42) wing trailing edge camber-morphing through SMA-based actuators.

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ALA-Smart Flap (2007-2008)

Morphing rib architecture: thinking out of the boxes …

Monolithic plate

Multi-body with conventional

hinges

Multi-body with elastic hinges

Multi-body with mechanic chains

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ALA-Smart Flap (2007-2008)

The inspiration: the arch shaped actuator

Concept design Analysis

Manufacturing

Tests

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3

2

4

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ALA-Smart Flap (2007-2008)

Actuator integration within the structure: rib concept characterized by a high level of integration

SMA ribbonElastic element

Not structural element (for shape only)

Morphed config.

Unmorphed config.

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ALA-Smart Flap (2007-2008)

Actuator integration within the structure: rib concept characterized by a low level of integration

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ALA-Smart Flap (2007-2008)

Main achievements of the project: actuation device and wing flap assembly successfully patented

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Clean Sky – GRA (phase 1, 2010-2012)Research objective: Design, manufacturing and validation of a morphing architecture enabling thecontrolled camber variation of a single flap element in compliance with target reference shapes.

2,7

2,8

2,9

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3,1

3,2

3,3

3,4

3,5

0 1 2 3 4 5 6 7 8alfa

cl

baselinebest

2,7

2,8

2,9

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3,1

3,2

3,3

3,4

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0 1 2 3 4 5 6 7 8alfa

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baselinebest

The definition of the target (morphed) shape was carried out by CIRA through 2D CFD optimizationanalyses at M = 0.2 and based on in-house RANS flow solvers.

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Clean Sky – GRA (phase 1, 2010-2012)Research objective: Design, manufacturing and validation of a morphing architecture enabling thecontrolled camber variation of a single flap element in compliance with target reference shapes.

Concept identification Preliminary design Advanced design

rib lay-out assessment

spars lay-out assessment

cross-links lay-out assessment

actuator/control system assess.

Advanced cinematic analysis Refined FE model and analyses

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Clean Sky – GRA (phase 1, 2010-2012)Research objective: Design, manufacturing and validation of a morphing architecture enabling thecontrolled camber variation of a single flap element in compliance with target reference shapes.

Experimental tests

Func. tests Static tests GVT

Prototype manufacturing

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Clean Sky – GRA (phase 1, 2010-2012)Research objective: Design, manufacturing and validation of a morphing architecture enabling thecontrolled camber variation of a single flap element in compliance with target reference shapes.

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SARISTU (2011-2015)

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SARISTU (2011-2015)

Definition of Requirements & Specifications

Design of the morph. structureAerodynamic design

TE box

Skin

Design of systems

Actuation & control

Sensing

Stressed layout emission / Aeroelastic assessment

Executive drawings and manufacturing of prototypes Experimental tests

investigation domains

0.35 m

0.7 m

Application scenario 2, adaptive TE: key partners ..

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SARISTU (2011-2015)

Application scenario 2, adaptive TE: the inner structure …

Baseline configuration

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SARISTU (2011-2015)

Application scenario 2, adaptive TE: the dummy demonstrators

ATE structure : executive layout

ATE structure : simplified layout

ATE structure : simplified demonstrator (dummy)

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SARISTU (2011-2015)

Application scenario 2, adaptive TE: AS02 demonstrator and qualification tests

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SARISTU (2011-2015)

Application scenario 2, adaptive TE: AS02 demonstrator and qualification tests

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SARISTU (2011-2015)

Application scenario 2, adaptive TE: AS02 demonstrator and qualification tests

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SARISTU (2011-2015)

From AS02 to IS12: 5-bay demonstrator

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SARISTU (2011-2015)From AS02 to IS12: for the firs time ever, a true scale wing segment equipped with 3 fully functionalmorphing devices will be tested in one of the largest WT of the world !

(TSAGI WT facility, Russia)

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CRIAQ-MDO505 (2012-2015)Research objective: Design, manufacturing and test of a morphing aileron as part of an integrated wingtip system devoted to increase aerodynamic efficiency in cruise.

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CRIAQ-MDO505 (2012-2015)

Coupled morphing device: morphable skin box + aileron with morphing camber capabilities

Canadian team responsibility

Italian team responsibility

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CRIAQ-MDO505 (2012-2015)

Morphing aileron: morphing box and actuation

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CRIAQ-MDO505 (2012-2015)

Morphing aileron: the sliding skin concept (high TRL)

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Clean Sky – GRA (phase 2, 2013-2015)

Phase 1 architecture was selected for follow-on activities addressing the design and the mechanical demonstration ofan advanced 3D prototype implementing similar but enhanced morphing solutions.The new device, is applicable to the NLF wing of the 130-seats GRA with rear fuselage power plant.

TRL 4/5(2015)

TRL 3(2012)

PHASE 1 OUTCOMESPHASE 1 OUTCOMES

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Clean Sky – GRA (phase 2, 2013-2015)

Overview of the work plan

Reworking of SACM morphing concept

Cinematic analysis of the 3DF morphing rib

Structural analysis of the 3DF morphing rib

Assessment of the single bay architecture

Cinematic and structural analysis of the single bay

Preliminary drawings of the 3DF prototype

Preliminary Design

Executive Design

Prototype manufacturing

Ground demonstration

Critical design review

PRELIMINARY 

DESIGN

ADVANCED DES. &

MAN

UFACTU

RING

TEST

Sep. 2015

Apr. 2015

May 2014

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Clean Sky – GRA (phase 2, 2013-2015)

Bi-modal morphing rib: mode 1 actuation

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Clean Sky – GRA (phase 2, 2013-2015)

Bi-modal morphing rib: mode 2 actuation

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Clean Sky – GRA (phase 2, 2013-2015)

Bi-modal morphing rib: morphing mode 1

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Clean Sky – GRA (phase 2, 2013-2015)

Bi-modal morphing rib: morphing mode 2

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Clean Sky – GRA (phase 2, 2013-2015)

Key-issues: fitting mechanisms in a tapered structure, design of a (large) sliding skin

Armadillo-like skin with syliconic seals

(only) 1st and last chordwise segments tapered. Straight hinge lines perpendicular to rib’s planes

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Clean Sky – GRA (phase 2, 2013-2015)

3DF architecture: morphing mode 1

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Clean Sky – GRA (phase 2, 2013-2015)

3DF architecture: morphing mode 2

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Clean Sky – GRA (phase 2, 2013-2015)

3DF architecture: the armadillo-like skin during morphing

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Clean Sky – GRA (phase 2, 2013-2015)

Executive Design

Prototype manufacturing

Ground demonstration

Critical design review

ADVANCED DES. &

MAN

UFACTU

RING

Sep. 2015

Apr. 2015

TEST

End of Preliminary DesignLayout refinement

Detailed FE modelsand analyses

Elaboration of the stressed layout

Definition of manufacturing tolerances

2D drawings and part list

(Manufact.) Time &Methods

Spare parts manufacturing

C.o.t.s. purchase

Final assembly

Control System design 

Control System Implementation 

Actuators purchase 

“Structure” path

“Equipment” pathMay 2014

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